FR2927162A1 - Refrigeration apparatus e.g. domestic refrigerator, has water supplying tube crown-molded at interior of sheath, and space containing air handled between tube and sheath, where air is maintained at temperature higher than specific Celsius - Google Patents

Abstract

The apparatus (1) has a water supply source positioned in upstream of an ice block fabricating device (12) that includes a water supplying tube supplying water to an ice-tray. The tube is connected to a water supply conduit, and is crown-molded at an interior of a sheath crossing a portion of an insulating wall (4) constituting a freezing enclosure (3). A space containing air is handled between the tube and the sheath, where the air is maintained at temperature higher than 0 degree Celsius.

Description

The present invention relates to a refrigeration apparatus and in particular a refrigerator. The present invention is particularly directed to supplying water to an ice-making device in a freezing compartment of a refrigeration apparatus. Fridges equipped with an ice-making device are already known. These ice-making devices placed in a freezing compartment are either supplied with water from above or from the rear. The water supplies of these ice-making devices are equipped with an electric heating system to prevent the formation of ice during the supply of water to one or more ice cube molds. A resistive heating element is wrapped around a water inlet tube opening at an ice cube mold to prevent the formation of ice in said water inlet tube. However, the water supplies of these ice-making devices have the drawback of requiring an electrical circuit supplying the resistive heating element to prevent the formation of ice in the water inlet tube opening at a ice cube mold. Moreover, these ice-making devices are equipped with a metal water inlet tube 20 and not a plastic tube since the latter is heated by a resistive heating element. Therefore, obtaining such ice-making devices is expensive and complex to implement. Many assembly operations are to be performed during the manufacture of refrigeration equipment and the number of parts is high. In addition, the use of a resistive heating element increases the consumption of electrical energy necessary for the operation of refrigeration equipment equipped with an ice making device. The present invention aims to solve the aforementioned drawbacks and to provide a refrigeration apparatus comprising a water supply for the manufacture of ice cubes automatically without water or drops of water freeze following the flow of ice. water from a source of water supply to one or more ice cube molds. To this end, the present invention is directed to a refrigeration apparatus, in particular a refrigerator, comprising a structure formed by insulating walls, and at least one freezing chamber comprising an opening on the front face closed by a door, said refrigerating apparatus comprising also a water supply source positioned upstream of an ice-making device, a water supply pipe extending between said water supply source and said ice-making device. According to the invention, the ice-making device comprises a water supply tube feeding at least one ice cube mold, said water supply tube being connected to said water supply pipe; b- said water supply tube is housed inside a sheath passing through at least a portion of an insulating wall constituting said at least one freezing chamber; and c) a space is provided between said water supply tube and said sleeve, said space containing air maintained at a temperature above 0 ° C. Thus, the formation of ice in the water supply tube opening near one or more ice cube molds is avoided by allowing the air contained in the space between the water supply tube to be maintained. and the barrel of the ice maker at a temperature above 0 ° C. The space between the water supply tube and the ice maker barrel allows air to infiltrate therebetween to reheat and hold said delivery tube free of moisture. water.

In this way, the formation of ice is avoided at the end of the water supply tube opening near an ice cube mold and the recessed portion of said water supply tube allowing the passage of water. the water. The ice making device according to the invention allows the passage of the water supply tube in a sleeve inserted into an insulating wall forming the freezing chamber. The space containing air formed between the water supply tube and the barrel of the ice-making device allows to heat and maintain frost-free said water supply tube. Said water supply tube is used to supply water to at least one ice cube mold placed in a freezing chamber. And the air contained in the space provided between the water supply tube and the sleeve of the ice-making device makes it possible to heat and maintain the said water supply tube out of freezing by passing through at least one insulating wall. forming the freezing chamber. The ice-making device according to the invention makes it possible to prevent the formation of ice inside the water supply tube and at its ends without requiring a caloric intake by expensive electrical means consuming energy. . In practice, the temperature of the air contained in the space between the tube -3-of water and the barrel is maintained at a value greater than 0 ° C. Thus, the temperature above 0 ° C of the air contained in the space between the water supply tube and the sleeve of the ice-making device makes it possible to prevent the formation of ice in said delivery tube. of water: According to a preferred feature of the invent on, the connection between the water supply pipe and the water supply pipe esi: housed inside a chamber closed by at least one housing . Thus, the connection between the water supply line and the water supply tube is isolated from said at least one freezing chamber of the refrigeration apparatus. The chamber enclosing the connection between the water supply line and the water supply tube enables the heat coming from a heat sink element belonging to the refrigerating apparatus or the ambient air to be conducted so that to limit the influence of the controlled temperature in said at least one freezing chamber.

The chamber of the connection between the water supply line and the water supply pipe makes it possible to maintain a threshold temperature value greater than 0 ° C. so as to prevent the formation of ice in said feed tube. 'water. The temperature value of the air contained in the chamber is dependent on the one hand on the temperature gradient of the housing and on the other hand on the temperature gradient of the sleeve inserted in at least one insulating wall forming said at least one freezing chamber . The air contained in the chamber warms the water supply tube and prevents the formation of ice in the latter. The preferably closed housing of the chamber enclosing the connection between the water supply line and the water supply tube also makes it possible to prevent the external moist air from entering the interior of said chamber. The Applicant has been able to observe during experiments that the temperature of the air in the chamber is lower than the temperature of the ambient ambient air around the refrigeration apparatus. Consequently, the cold walls of the sheath tend to attract the moisture present in the outside ambient air. The housing, preferably closed, of the chamber avoids the accumulation of moisture at the water supply tube and therefore the risk of ice formation thereon. Preferably, the chamber enclosing the connection between the water supply pipe and the water supply pipe is sealed to the ambient air. Other features and advantages of the invention will become apparent in the description below. In the accompanying drawings, given by way of nonlimiting example: FIG. 1 is a first schematic view illustrating a combined refrigeration apparatus, including a freezing chamber and a refrigeration chamber closed by doors in the open position; according to one embodiment of the invention; FIG. 2 is a second schematic view illustrating a combined refrigeration apparatus similar to FIG. 1, comprising a condenser extending on the rear face, according to one embodiment of the invention; - Figure 3 is a schematic perspective view of an ice making device according to the invention; - Figure 4 is a schematic sectional view of a refrigeration apparatus comprising an ice making device according to one embodiment of the invention; FIG. 5 is a diagrammatic view from above of an ice-making device according to the invention; and FIG. 6 is a diagrammatic detail view in section of a water supply of an ice-making device according to one embodiment of the invention.

We will first describe with reference to Figures 1 and 2 a combined refrigeration apparatus according to the invention. This combined refrigeration unit 1 comprises a refrigeration chamber 2 at the top and a freezing chamber 3 at the bottom. The refrigeration apparatus 1 comprises insulating walls 4 forming the refrigerating chamber 2 and the freezing chamber 3. The insulating walls 4 comprise an internal surface 4a defining the space of the refrigerating chamber 2 and the freezing chamber 3. This inner surface 4a is contained in an outer casing 4b. An insulating layer is provided between the inner surface 4a and the outer casing 4b of the refrigeration enclosure 2 and the freezing enclosure 3. This insulating layer may be made by the foam and / or by empty of air. The refrigeration apparatus 1 comprises at least one evaporator (not shown). An evaporator may be disposed in the insulation layer and in contact with the inner surface 4a of the refrigerating chamber 2 and the freezing chamber 3. The evaporator may be included in one of the insulating walls 4 or in the three vertical walls or at least two of the cooling chamber 2 and the freezing chamber 3. The evaporator may be in thermal relation with only a part of said insulating walls 4. The evaporator may also be placed in the lower part of the freezing chamber 3.

The combined refrigeration apparatus 1 comprises a refrigerating chamber 2 and a freezing chamber 3 closed respectively by a door 5, 6. The refrigerating chamber 2 and the freezing chamber 3 provided with a thermal insulation material in which is incorporated the evaporator forms part of the refrigeration circuit of the refrigeration apparatus 1.

The refrigeration chamber 2 and the freezing chamber 3 of the refrigerating apparatus 1 comprising a refrigeration circuit (not shown) are adapted to maintain a temperature within a predetermined range of values. The regulation of the temperature of the refrigerating chamber 2 and the freezing chamber 3 is guaranteed by control means (not shown) of the refrigeration and temperature measurement circuit. The refrigeration circuit also comprises a condenser 7, illustrated in FIG. 2, positioned behind the refrigerating chamber 2 and the freezing chamber 3. This condenser 7 is assembled on a rear wall 8 constituting the body 9 of the apparatus refrigeration 1.

The refrigeration circuit comprises all the conventional elements constituting such a device and well known to those skilled in the art. These elements are not shown in the figures. The freezing chamber 3 may include removable drawers and / or shelves for storing food to keep.

A device for making ice cubes and in particular the water supply of this device according to one embodiment of the invention will now be described with reference to FIGS. 1 to 6. A refrigeration apparatus 1, in particular a refrigerator, comprises a structure formed by insulating walls 4, and at least one freezing chamber 3 comprising an opening 10 on the end face 11 closed off by a door 6. The air temperature in a freezing chamber 3 is at least of the order of -18 ° C. The refrigeration apparatus 1 also comprises a water supply source positioned upstream of an ice-making device 12. The ice-making device 12 may comprise a system for demolding the ice cubes by elastically deforming an ice cube. ice cube mold 17 by exerting a torsion force on the latter. The ice cube mold 17 may be rotated by a motorized drive system engaging a stopper and causing a twisting force on said ice cube mold 17. When the ice cubes are removed from the ice cube mold 17, these fall into an ice bin 25 located below said ice cube mold 17. A water supply pipe 13 extends between the water supply source and the ice-making device 12. The device The opening of the solenoid valve 20 controlled by means of control of the refrigerating apparatus 1 makes it possible to fill one or more ice cube molds with water. The solenoid valve 20 is preferably located in the lower part of the refrigerating apparatus 1. The solenoid valve 20 is connected to the water supply pipe 13 so as to raise the water at the level of the apparatus ice cubes 12. The solenoid valve 20 is also connected to the water supply source, which may for example be a drinking water system. The solenoid valve 20 makes it possible to produce a column of water inside the water supply pipe 20. This water column extends from the solenoid valve 20 situated at the bottom of the refrigeration apparatus. 1 to the connection between the water supply pipe 13 and a water supply pipe 14 The connection between the water supply pipe 13 and the water supply pipe 14 is in the form of a elbow and delimits the height of the water column contained in said water supply line 13. The ice-making device 12 comprises a water supply tube 14 feeding at least one ice cube mold 17 The water supply tube 14 is connected to the water supply line 13. The water supply tube 14 is a rigid tube, preferably made of a plastic material, and the supply line water 13 is a flexible pipe, preferably made of a material such as polypropylen ene. The water supply pipe 13 is force-fitted at a bent end of the water supply tube 14. The water supply pipe 14 is housed inside a sheath 15 passing through at least one a part of an insulating wall 4 constituting said at least one freezing chamber 3. The sleeve 15 is embedded in an insulating wall 4 which may consist of an insulating foam. The sheath 15 guides the water supply tube 14 to an ice cube mold 17 of the ice-making device 12. A space 16 is formed between the water supply pipe 14 and the sheath 15 5 containing air maintained at a temperature above 0 ° C. Thus, the formation of ice in the water supply tube 14 opening in the vicinity of one or more ice cube molds 17 is avoided by stabilizing the temperature of the air contained in the space 16 formed between the water supply tube 14 and the sleeve 15 of the ice-making device 12. The temperature inside the space 16 formed between the sleeve 15 and the water supply tube 14 is preferably the order of 7 ° C. Thus, the temperature of the air contained inside the water supply pipe 14 and in the part near the water column formed in the water supply pipe 13 is kept at a positive temperature. that is above 0 ° C, to avoid any risk of frost. The temperature of the air contained inside the water supply tube 14 is greater than 0 ° C upstream of the zone where the sleeve 15 is embedded in an insulating wall 4 of the freezing chamber 3. The water supply tube 14 has an end opening into the freezing chamber 3 through an insulating wall 4. The portion of the water supply tube 14 opening into the freezing chamber 3 is kept empty of water and preferentially ventilated to avoid any risk of frost. The gap 16 between the water supply tube 14 and the barrel 15 of the ice maker 12 allows air to infiltrate therebetween to warm and hold the tube free from frost. In this way, the formation of ice is avoided at the end of the water supply tube 14 opening in the vicinity of an ice cube mold 17 and the recessed portion of said tube of water. supply of water 14 allowing the passage of water. The ice-making device 12 allows the passage of the water supply tube 14 in a sleeve 15 inserted in an insulating wall 4 forming the freezing chamber 3. The space 16 containing air formed between the water supply pipe 14 and the sleeve 15 of the ice-making device 12 makes it possible to heat and maintain the said water-supply tube 14 out of freezing. Said water supply tube 14 supplies 35 in water at least one ice cube mold 17 placed in a freezing chamber 3. And the air contained in the space 16 formed between the water supply tube 14 and the sleeve 15 of the ice-making device 12 allows to heat and maintain frost-free said water supply tube 14 by passing through at least one insulating wall 4 forming the freezing chamber 3. The ice-making device 12 prevents the formation of ice-cream the inside of the water supply tube 14 and its extemities without requiring a caloric energy by expensive electrical means and energy consumers. The space 16 containing air inside the sheath 15 extends along the length of the water supply tube 14 so as to heat said water supply tube 14 over its entire length. The water supply tube 14 is preferably of cylindrical or conical shape and the sleeve 15 of conical shape with different sections. In this way, the space 16 formed between the water supply tube 14 and the sheath 15 may have a section evolving along the length of said sheath 15. The smallest section of space 16 is located at end of the water supply pipe 14 opening at an ice cube mold 17. In this way, the cold air of the freezing chamber 3 has a small influence on the air contained in the space 16 arranged between the water supply tube 14 and the sleeve 15 by limiting the heat exchange between the freezing chamber 3 and the water supply tube 14. The sleeve 15 has a top wall 15a in the form of a spout at one end opening near an ice cube mold 17.

Thus, the water flowing into the water supply pipe 14 is directed towards a ice cube mold 17 by the upper wall 15a in the shape of a beak of the sheath 15 as soon as the water comes out of said tube 14. The upper wall 15a in the shape of a beak of the sheath 15 may also comprise a baffle (not shown) so as to disperse the jet of water leaving the water supply pipe 14 in a multitude The water supply tube 14 is of substantially conical shape in order to facilitate the demolding of this part made of plastic material. The large inner diameter of the water supply tube 14 is substantially of the order of 15 mm and the small inside diameter of said water supply tube 14 is substantially of the order of 11 mm.

In practice, the temperature of the air contained in the space 16 formed between the water supply tube 14 and the sleeve 15 is maintained at a value greater than 0 ° C. Thus, this temperature greater than 0 ° C of the air contained in the space 16 between the water supply tube 14 and the sleeve 15 of the ice-making device 12 makes it possible to prevent the formation of ice in said water supply tube 14.

In one embodiment of the invention illustrated in Figure 6, the sleeve 15 enclosing the water supply tube 14 comprises two parts. The first part 15 'of the sleeve 15 makes it possible to create the space 16 formed between said sleeve 15 and the water supply tube 14. In this first part 15' of the sleeve 15 is contained air at a temperature above 0 ° C. At the end of this first portion 15 'of the sleeve 15, the space 16 formed between the sleeve 15 and the water supply tube is closed by a partition wall 21.

The temperature of the air inside the water supply tube 14 is substantially equal to 0 ° C. at the level of the partition wall 21 formed in the sleeve 15 separating the first part 15 'from the second part The second portion 15 "of the sleeve 15 contains the water supply tube 14 with a spacing therebetween allowing a narrower air passage than in the first portion 15 'of the sleeve 15. The wall of separation 21 makes it possible to center the water supply pipe 14 inside the sheath 15. The partition wall 21 also makes it possible to thermally separate the first portion 15 'and the second portion 15 "of the sheath 15. separation 21 15 thus makes it possible to obtain an effect on the temperature of the air contained in the water supply tube 14. The separation wall 21 makes it easier to maintain the temperature of the air contained in the tube supply of water 14 at a temperature above 0 ° C, especially in the part of the water supply tube 14 surrounded by the space 16 formed between the sheath 15 and said water supply tube 14. The partition wall 21 between the first part 15 'and the second part 15 " the sheath 15 is not necessarily sealed and can allow the air to communicate between the zone situated upstream and the zone situated downstream of said partition wall 21. The air contained in the space 16 formed between the first part 15 'of the sleeve 15 and the water supply tube 14 is maintained at a temperature above 0 ° C, whatever the thickness of the insulating wall 4 through which the sleeve 15 opens in the vicinity of a mold to ice cube 17 placed in the freezing chamber 3. The height H of the second portion 15 "of the sheath 15 is determined according to the thickness of the insulation wall 4. The height H of the second portion 15" of the sheath 15 allows to determine the position of the end of the space between the sleeve 15 and the water supply tube 14. According to the tests carried out by the Applicant, the height H of the second portion 15 "of the sleeve 15 may be of the order of 26 mm for an insulating wall of 40mm thick. The total length of the water supply tube 14 may be of the order of 250mm. The height H of the second portion 15 "of the sleeve 15 is determined so that the temperature of the air contained in the space 16 formed between the water supply tube 14 and the sleeve 15 is above 0 ° C. In order to guarantee a positive temperature, that is to say greater than 0 ° C., in the space 16 formed between the water supply pipe 14 and the sheath 15, the thickness the insulating wall 4 of the freezing chamber 3 through which the sleeve 15 passes must be of sufficient size to prevent heat losses from the freezing enclosure 3 towards the outside, the length of the second portion 15 "of the sleeve 15 is determined according to the minimum height H allowing the thermal insulation of the freezing chamber 3. The length of the second portion 15 "of the sleeve 15 is preferably of the order of 130 mm, of course, the values of the dimensions specified previously of the water supply tube 14, the sheath 15 are given by way of example and are in no way limiting. Moreover, the thickness of the insulating walls 4 of the freezing chamber 3 must be of sufficient size to avoid a degradation of the characteristics of the refrigeration apparatus, and in particular of the energy class of said refrigeration apparatus 1. The walls insulators 4 must respect a minimum thickness in order to obtain the necessary insulation characteristics for the freezing chamber 3 of the refrigerating apparatus 1. The temperature of the air contained in the water supply tube 14 is the order of 0 ° C to the right of the partition wall 21. The distance between the second portion 15 "of the sleeve 15 and the water supply tube 14 represents a minimum clearance for the assembly and construction of the device 12 This distance between the second portion 15 "of the sleeve 15 and the water supply tube 14 also makes it possible to sublimate all traces of ice and water to flow. The ice maker 12 comprises a housing 26 enclosing the ice cube mold 17. This housing 26 is vented by air entering through at least one opening 27. The air 30 can be introduced into the housing 26 by a fan (not shown) blowing through said at least one opening 27. This ventilated air can flow beforehand along an evaporator (not shown) and thus achieve a temperature of the order of -25 ° C during its introduction into the housing 26 of the ice-making device 12. In this way, a drop of water frozen at the end of the water supply tube 14 opening into the freezing chamber 3 can be sublimated. The temperature of the air inside the ice maker 12 is preferably at least about -20 ° C. The ice maker 12 is vented by air from the evaporator and entering through at least one opening 27 in the housing 26 of said ice maker 12.

A drop of water flowing in the water supply tube 14 may freeze at the end of said water supply tube 14 opening into the freezing chamber 3. This frozen water drop is sublimated by the flow of cold air F from the evaporator and flowing inside the casing 26 of the ice maker 12. The flow of air F from the evaporator and flowing inside the casing 26 the ice-making device 12 makes it possible, on the one hand, to prevent the formation of ice at the end of the water supply tube 14 opening into the freezing chamber 3 and, on the other hand, to dry out the air contained in the housing 26 of said ice-making device 12. The end of the water supply tube 14 opening into the freezing chamber 3 is located close to said at least one opening 27 of the device housing 26 of making ice cubes 12 in order to guarantee the sublimation of a drop of frozen water at said end of the water supply tube 14. The connection between the water supply pipe 13 and the water supply tube 14 is housed inside a chamber 18 closed by at least one housing 19.

Thus, the connection between the water supply pipe 13 and the water supply tube 14 is isolated from said at least one freezing chamber 3 of the refrigeration apparatus 1. The chamber 18 enclosing the connection between the water supply pipe 13 and the water supply tube 14 can conduct the heat from a heat sink element belonging to the refrigeration unit 1 or ambient air so as to limit the influence of the controlled temperature in said at least one freezing chamber 3. Indeed, the presence of a heat sink element can facilitate the heating of the air contained in the space 16.

In the case where the ice making device 12 is placed in the upper part of the back of the refrigeration apparatus 1, by natural convection the air temperature would increase by the heat released by a heat sink element and / or d a motor-compressor, said heat rising to the rear of said refrigeration apparatus 1 along the rear wall 8 of the body 9.

This configuration could be reproduced on the top of the refrigeration unit 1 in horizontal part provided to arrange a collector to recover the heat from the back of said refrigeration apparatus 1. -12- The chamber 18 of the connection between the pipe supplying water 13 and the water supply tube 14 makes it possible to maintain a temperature threshold value greater than 0 ° C. so as to avoid the formation of ice in said water supply tube 14. The value the temperature of the air contained in the chamber 18 is dependent, on the one hand, on the temperature gradient of the housing 19 and, on the other hand, on the temperature gradient of the sleeve 15 inserted into at least one insulating wall 4 forming said at least one enclosure 3. The air contained in the chamber 18 heats the water supply tube 14 and prevents the formation of ice therein.

The housing 19, which is preferably closed, also makes it possible to keep the water supply tube 14 in position in the chamber 18 and in the direction of an ice cube mold 17. The preferably closed housing 19 of the chamber 18 enclosing the connection between the water supply pipe 13 and the water supply tube 14 also prevents the external moist air from entering the interior of said chamber 18. The Applicant was able to observe during the Experiments that the temperature of the air in the chamber 18 is lower than the temperature of the surrounding ambient air around the refrigeration apparatus 1. Therefore: the cold walls of the sleeve 15 tend to attract the moisture present in outdoor ambient air. The housing 19, preferably closed, of the chamber 18 prevents the accumulation of moisture at the water supply tube 14 and therefore the risk of ice formation thereon. The volume of air contained in the chamber 18 and the space 16 is in a range extending between 0.1 liter and 0.4 liter, and preferably of the order of 0.3 liter. Preferably, the chamber 18 enclosing the connection between the water supply pipe 13 and the water supply pipe 14 is airtight. The housing 19 of the chamber 18 is of substantially parallelepipedal shape and is assembled on the rear wall 8 of the body 9 of the refrigeration apparatus 1.

The housing 19 comprises an opening 22 permitting the passage of the water supply pipe 13. The chamber 18 is formed on the one hand by a housing 19 and on the other by a wall 23 of the sheath 15. The sheath 15 comprises reinforcement elements 24 extending between the conical portion and the wall 23 so as to ensure the rigidity of this part. In one embodiment of the invention, the ambient ambient air heats the air contained in the space 16 formed between the water supply tube 14 and the sleeve 15 of the ice-making device 12 by creating a heat exchange. In a preferred embodiment of the invention, the chamber 18 enclosing the connection between the water supply pipe 13 and the water supply tube 14 is in thermal relation with a condenser 7 of a circui •: for refrigeration of said refrigeration apparatus 1. The housing 19 closing the chamber 18 is placed in the upper part of the freezing chamber 3 and at the rear of the refrigerating apparatus 1. The housing 19 is also located near the a condenser 7. The condenser 7 is integrated in the refrigeration circuit of the refrigerating apparatus 1 and has a temperature higher than that of the ambient air. This condenser 7 is located after a compressor in the thermodynamic chain and has the role of cooling the compressed gas refrigeration circuit and liquefying to supply the rest of the refrigeration circuit. The condenser 7 is constantly warmer than the ambient air, and generally in a range of about 5 to 10 ° C above the ambient air around the refrigerating appliance 1. The temperature ambient air around the refrigeration apparatus 1 and located near the chamber 18 enclosing the connection between the water supply pipe 14 and the water supply pipe 13 is preferably of the order of 30 ° C.

Therefore, the housing 19 located near the condenser 7 and in thermal relation with it is heated. The housing 19 thus transmits the heat by conduction to the air contained in the chamber 18 and the space 16 formed between the sleeve 15 and the water supply tube 14. The chamber 18 and the space 16 arranged between the sleeve 15 and the water supply tube 14 forms only a single set containing air. Advantageously, the sheath 15 is inclined by an angle α so that the water flows into the water supply tube 14. Thus, the water flows into the feed tube of water 14 without stagnating. The inclination of an angle of the sheath 15 is also applied to the water supply tube 14 since the latter are aligned on a common axis X. The inclination of an angle a of the water supply pipe 14 makes it possible to maintain a flow rate of the water inside thereof during the water filling of an ice cube mold 17. The water supply pipe 14 is firstly sloped with respect to a horizontal plane so that the water can flow by gravity from the connection between the water supply pipe 13 and said water supply tube 14 to the ice cube mold 17. On the other hand, the water supply tube 14 is preferably made of a material having a low coefficient of friction and the state of surface of the inner wall of said water supply tube 14 is smooth. In this way, the water flows rapidly into the water supply tube 14 and the water droplets do not catch on the inner wall of said water supply tube 14 so as to avoid that the water does not freeze before its arrival at the end of said water supply tube 14 opening above the ice cube mold 17. In the case where a drop of water freezes at the end of the tube of When the water supply 14 opens above the ice cube mold 17, it disappears by sublimation 10 since the refrigerating apparatus 1 is equipped with a ventilated cold device as described above. The material of the water supply tube 14 is chosen so that the interface energy between the water and the material of said water supply tube 14 is as low as possible.

The surface condition of the inner wall of the water supply tube 14 should be preferably ice-polished, the term ice-polish being usually employed in the field of molding plastics. The sleeve 15 allows to support and guide the water supply tube 14 in a direction and inclination of an angle a. In this way, the water flowing into the water supply tube 14 falls by gravity into an ice cube mold 17. The inclination of an angle α of the water supply tube 14 and the sheath 15 makes it possible to prevent the formation of ice at the ends and inside of said water supply tube 14. The inclination of an angle α of the sheath 15 is in a range extending between 10 ° and 90 °, and preferably at least 15 °.

In the embodiment of the invention described above, the volume of air constituted by the chamber 18 and the space 16 is closed and without air circulation. The frost-free heating of the water supply tube 14 is thus ensured by a heat exchange consisting of a conduction and a thermal radiation through the housing 19 of the chamber 18.

In another embodiment of the invention, the volume of air formed by the chamber 18 and the space 16 may be heated by forced air circulation.

Claims (7)

Refrigerating apparatus (1), in particular a refrigerator, comprising a structure formed by insulating walls (4), and at least one freezing chamber (3) comprising an opening (10) on the end face (11) closed by a gate (6), said refrigeration apparatus (1) also comprising a water supply source positioned upstream of an ice-making device (12), a water supply pipe (13) extending between said water supply source and said ice-making device (12), characterized in that: a- the ice-making device (12) comprises a water supply tube (14) supplying at least one an ice cube mold (17), said water supply tube (14) being connected to said water supply pipe (13); b- said water supply tube (14) is oged inside a sheath (15) passing through at least a part of an insulating wall (4) constituting said at least one freezing chamber (3) ; and c) a space (16) is provided between said water supply tube (14) and said sleeve (15), said space (16) containing air maintained at a temperature above 0 ° C. 2- refrigeration apparatus according to claim 1, characterized in that the connection between the water supply pipe (13) and the water supply tube (14) is housed inside a chamber ( 18) closed by at least one housing (19). 3- refrigeration apparatus according to claim 2, characterized in that the chamber (18) enclosing the connection between the water supply pipe (13) and the water supply pipe (14) is in thermal relation with a condenser (7) of a refrigeration circuit of said refrigeration apparatus (1). 4- refrigeration apparatus according to claim 2, characterized in that the ambient ambient air heats the air contained in the space (16) formed between the water supply tube (14) and the sleeve (15) the ice-making device (12) by creating a heat exchange. 5. Refrigeration appliance according to claim 4, characterized in that the chamber (18) enclosing the connection between the water supply pipe (13) and the water supply pipe (14) is watertight. ambiant air. 6. Refrigeration apparatus according to any one of claims 1 to 5, characterized in that the sheath (15) is inclined by an angle (a) so that the water flows into the tube of supply of water (14). 7- refrigerating apparatus according to claim 6, characterized in that the inclination of an angle (a) of the sheath (15) is in a range extending between 10 ° and 90 °, and preferably at minimum of 15 °.